Aging does not alter muscarinic receptor-mediated inhibition of cyclic AMP formation in the striatum and hippocampus

Carotid body gap junctions: secretion of transmitters and possible electric coupling between glomus cells and nerve terminals

It is proposed that intercellular coupling between glomus cells and carotid nerve terminals form an integral part of the chemoreceptor process. Coupling is possible because gap junctions occur between these elements. At rest, most glomus cells would be coupled. Stimuli uncouple (or reduce coupling) most glomus cells that extrude their contents toward the nerve terminals. However, other glomus cells do not secrete but recharge and intercellular coupling increases. These phenomena would allow for sustained chemoreceptor activity during prolonged stimulation. Coupling between glomus and sustentacular cells may explain why the behavior of glomus cells in the intact carotid body and when clustered in cultures (when their sustentacular envelope is preserved) is different from that of isolated cells where sustentacular cells are destroyed. The presence of electric synapses between glomus cells and nerve terminals may explain the poor performance of synaptic blockers on natural (hypoxia, hypercapnia, acidity) carotid body stimulation.

Vitamin K-dependent proteins in the developing and aging nervous system

Although the warfarin embryopathy syndrome, with its neurologic and bone abnormalities, has been known for decades, the role of vitamin K in the brain has not been studied systematically. Recently, it was demonstrated that vitamin K-dependent carboxylase expression is temporally regulated in a tissue-specific manner with high expression in the nervous system during the early embryonic stages and with liver expression after birth and in adult animals. This finding, along with the discovery of wide distribution of the novel vitamin K-dependent growth factor, Gas6, in the central nervous system, provides compelling evidence of a biologic role of vitamin K during the development of the nervous system. In animals and bacteria, vitamin K was observed to influence the brain sulfatide concentration and the activity and synthesis of an important enzyme involved in brain sphingolipids biosynthesis. Taken together, previous research results point to a possible role of vitamin K in the nervous system, especially during its development. Hence, the knowledge of the biologic role of vitamin K in the brain may be important for unveiling the mechanisms of normal and pathologic development and aging of the nervous system. The role of the vitamin K-dependent protein Gas6 in activation of signal transduction events in the brain in light of the age-related changes in the nervous system is also discussed.

Membrane and receptor modifications of oxidative stress vulnerability in aging. Nutritional considerations

Evidence suggests that oxidative stress (OS) may contribute to the pathogenesis of age-related decrements in neuronal function and that OS vulnerability increases as a function of age. In addition to decreased endogenous protection, increases in OS vulnerability may result from changes in membrane lipids and distribution of receptor subtype. Using a PC-12 cell model system, we have shown that H2O2 or dopamine (DA) exposure induced deficits in the cell's ability to clear (extrude/sequester, E/S) Ca2+ that are similar to those seen in aging. When plasma membrane concentrations of sphingomyelin (SPM) were used, the SPM metabolite, sphingosine-1-phosphate was increased to the same levels as those seen in aging, and enhancement of OS-induced decreases in calcium E/S following KCL depolarization was observed. Differential decreases in CA2+ E/S were also seen following DA-induced OS in COS-7 cells transfected with one of five muscarinic receptor subtypes. Cells transfected with either M1, M2, or M4 receptors showed significantly greater vulnerability to OS (as expressed by greater decrements in calcium E/S and cell death) than those transfected with M3 or M5 receptors. The vitamin E analogue, Trolox, and the nitrone-trapping agent, PBN, were not effective in altering E/S decrements but were effective in preventing cell death 24 h after OS exposure. These findings suggest that putative regional (e.g., striatum and hippocampus) increases in OS vulnerability and loss of neuronal function in aging may be dependent upon membrane SPM concentration and receptor subtype. In related studies, attempts were made to determine whether increased OS protection via nutritional increases in antioxidant levels in rats [using diets supplemented with vitamin E (500IU/kg), strawberry extracts (9.4 g/kg dried aqueous extract, DAE), spinach (6.7 g/kg DAE), or blueberry extracts (10 g/kg DEA for six weeks)] would protect against exposure to 100% O2 (a model of accelerated neuronal aging). Results indicated that these diets were effective in preventing OS-induced decrements in several parameters (e.g., nerve growth factor decreases), suggesting that although there may be increases in OS vulnerability in aging, phytochemicals present in antioxidant-rich foods may be beneficial in reducing or retarding the functional central nervous system deficits seen in aging or oxidative insult.

Nicotinic and muscarinic cholinergic receptor binding in the human hippocampal formation during development and aging

High-affinity nicotine, alpha-bungarotoxin (alpha BT) and muscarinic receptor binding was measured in the human hippocampal formation in a series of 57 cases aged between 24 weeks gestation and 100 years. Changes in nicotine receptor binding during development and aging were more striking than differences in alpha BT and muscarinic binding. Nicotine binding was higher at the late foetal stage than at any other subsequent time in all areas investigated. In the hippocampus a fall in binding then occurred within the first six months of life, with little or no subsequent fall during aging, whereas in the entorhinal cortex and the presubiculum the major loss of nicotine binding occurred after the fourth decade. alpha BT binding was significantly elevated in the CA 1 region, but in no other region of the hippocampus, in the late foetus, and there was also a fall in alpha BT binding in the entorhinal cortex during aging from the second decade. The modest changes in total muscarinic binding, which appeared to reflect those in M1 and M3 + 4 rather than M2 binding, were a rise in the entorhinal cortex between the foetal stage and childhood and a tendency for receptors to fall with age in the hippocampus and subicular complex. These findings implicate mechanisms controlling the expression of nicotinic receptors to a greater extent than muscarinic receptors in postnatal development and aging in the human hippocampus.

Age-related decline in cholinergic synaptic transmission in hippocampus

Age-dependent changes in central nervous system (CNS) cholinergic synaptic transmission were studied in three age groups of Sprague-Dawley and Fischer 344 rats: 1- to 2-month-old, 8- to 10-month-old, and 18- to 23-month-old. Utilizing intracellular recording techniques and the in vitro hippocampal slice preparation, we report an age-related decline in central cholinergic transmission as a function of age. Slow excitatory postsynaptic potentials (slow EPSPs) were reduced approximately 60% in aged (18- to 23-month-old) compared to younger (1- to 2-month-old) animals. The response of the postsynaptic membrane to the muscarinic agonist, carbachol (0.3 microM), was also reduced with age. These changes were not accompanied by a global decline in muscarinic receptor function since two additional measures of cholinergic function were not changed with age. Both presynaptic inhibition of fast excitatory synaptic transmission and postsynaptic inhibition of the afterhyperpolarization (AHP) following a train of spikes were not changed during aging. Our results suggest that a primary functional decline in central cholinergic mechanisms during aging may be a specific reduction in central cholinergic synaptic transmission.

Improving effect of acetylcholine receptor agonists on a deficit of 2-deoxyglucose uptake in cerebral cortical and hippocampal slices in aged and AF64A-treated rats

The aim of the present study was to determine whether the facilitation of 2-deoxyglucose (2-DG) uptake in the cerebral and hippocampal slices by nicotinic and muscarinic receptor agonists is compromised in the aged rat brain. For this, the effects of the nicotinic receptor agonist nicotine, the muscarinic receptor agonists oxotremorine and McN-A-343, and the ACh esterase inhibitors physostigmine and NK247 on 2-DG uptake in the brain slices of young (2-month-old) and aged (24-26-month-old) rats were tested. The decrements of 2-DG uptake in the cortical slices of aged rats were significantly attenuated by treatment with oxotremorine, nicotine and amiridine. In contrast, the metabolic responsivity of hippocampal slices to these drugs was reduced. To assess whether age-related changes in 2-DG uptake may be due to deficits in cholinergic function, we tested these drugs on the decrements of 2-DG uptake in ethylcholine aziridinium (a neurotoxic analog of choline) injected rats. The reductions of 2-DG uptake by injection of ethylcholine aziridinium was attenuated by oxotremorine but not by physostigmine. The present results reveal that metabolic decrements in the cerebral cortex from aged or ethylcholine aziridinium-injected rats were attenuated by muscarinic and nicotinic receptor agonists, suggesting that the muscarinic and nicotinic receptor mechanism in the cerebral cortex may be involved in cholinergic drug-induced functional recovery in aged rats.

A comparison of the regulatory properties of striatal and cortical adenylate cyclase

Biochemical properties of adenylate cyclase in striatal and cortical membranes have been analyzed in parallel with their regulation by cholinergic compounds. Striatal adenylate cyclase is more sensitive to forskolin, while the cortical enzyme is more stimulated by GTP. In the presence of GTP, more inhibition by acetylcholine is seen in the cortex than in the striatum. Acetylcholine inhibits striatal adenylate cyclase activity equally in the presence or absence of forskolin but has a diminished ability to inhibit forskolin-stimulated adenylate cyclase in the cortex. The greater sensitivity of cortical muscarinic receptor-coupled adenylate cyclase to EGTA and calcium indicates predominant involvement of the calcium/calmodulin-dependent subtype of the enzyme. The relative effectiveness of antagonists, demonstrating an order of potency of atropine > amitriptyline > pirenzepine > gallamine in reversing the inhibition of adenylate cyclase by acetylcholine for both brain regions, suggests predominantly m4 receptor-mediated responses. These results suggest an m4-type receptor may be coupled to subtypes of adenylate cyclase in the striatum and cortex which differ in their biochemical properties.

Age-related alterations in the properties of hippocampal pyramidal neurons among rat strains

We compared age-related alterations in the electrophysiological and pharmacological properties of CA1 hippocampal pyramidal neurons in three strains of rats (Sprague-Dawley, Fisher 344, and Wistar) at 3-4 and 25-32 months of age, using the in vitro slice preparation. The most consistent age-related alterations in the properties of rat hippocampal neurons were: a decrease in membrane excitability, a decrease in the amplitude and duration of inhibitory postsynaptic potentials and a decreased sensitivity to the effect of the cholinergic agonist carbachol. In contrast, no consistent alterations in calcium-dependent events were observed in these strains of rats. The age-related changes in the duration of the afterhyperpolarizations (AHPs) were different (and even opposite) depending on the strain studied. Our results show that age-related changes observed in a given strain are not necessarily present in all strains of the same species.

Comparison of the level of mRNA encoding m1 and m2 muscarinic receptors in brains of young and aged rats

We compared the concentration of mRNA encoding the m1 and m2 muscarinic receptors in several brain regions obtained from young (5-8 months) and aged (24-28 months) male Fischer 344 rats. DNA-excess solution hybridization was employed as a quantitative measure of mRNA concentration. The results indicate the absence of changes in the m1 receptor message with aging in the cerebral cortex, hippocampus and striatum. While there was no statistically significant aging-associated alteration in the concentration of the message encoding the m2 receptor in the thalamus, midbrain, cerebellum and brainstem, there was a decrease in the message level in the hypothalamus.

The putative role of free radicals in the loss of neuronal functioning in senescence

One of the hallmarks of the aging process is a loss of sensitivity in central neuronal receptors to agonist stimulation. This appears to be especially true in central (hippocampal, striatal) muscarinic cholinergic systems and in the striatal dopamine systems. For these two systems, any decline in their sensitivity can be of extreme importance in determining the behavioral capabilities of the organism. Decrements in the striatal dopamine system may be reflected as motor behavioral deficits, while the central cholinergic systems play a major role in the processing of memory through the activation of muscarinic receptors (mAChR). Declines in the function of these receptors appear to be at least partially responsible for the marked deterioration of cognitive function in normal aging and, more notably, in Alzheimer's disease (AD). Previous work has indicated only minimal success in improving performance in tasks that assess memory in senescent animals or humans with pharmacological agents which enhance cholinergic functioning. The present review describes research that indicates that two of the factors involved in this decline in receptor sensitivity include: (a) decreased receptor concentrations and (b) age-related decrements in signal transduction pathways. Studies are reviewed that indicate that the oxidative neural damage that occurs via kainic acid or ionizing radiation parallel those seen in aging. It is suggested that the common mechanism that may exist among all of the age-, disease-, excitatory amino acid- or radiation-induced deficits in neuronal transmission may involve free-radical-mediated alterations in membrane integrity through lipid peroxidation.

Muscarinic receptor concentrations and dopamine release in aged rat striata

The extent to which age-related decreases in muscarinic enhancement of K(+)-evoked dopamine release (K(+)-ERDA) from perifused striatal slices is dependent upon the loss of striatal muscarinic receptors (mAChR) was determined. Both K(+)-ERDA and mAChR (M1, M2) concentrations were assessed from the same animals (3, 5-7 and 24-27 months). Results indicated associated decreases of 70% in oxotremorine-enhanced K(+)-ERDA and 36% in Bmax (3H-QNB) (3 and 24-27 months groups). Decrease of mAChR Bmax was not the result of membrane sequestration. Although both the concentrations of M1 and M2 muscarinic receptor subtypes decline with age, only the M2 receptor decline was correlated with the age-related decreases in muscarinic enhancement of K(+)-ERDA (r = .71, p less than 0.001). Results suggest that age-related decreases in mAChR concentrations as being partially responsible for deficits in muscarinic enhancement of K(+)-evoked release of DA.

Lack of desensitization of muscarinic receptor-mediated second messenger signals in rat brain upon acute and chronic inhibition of acetylcholinesterase

We studied the effects of acute and chronic in vivo inhibition of acetylcholinesterase on both the density and function of brain muscarinic cholinergic receptors. Adult male rats were treated either once or multiple times over a period of 10 days with the irreversible acetylcholinesterase inhibitor diisopropylfluorophosphate (DFP). The concentration and affinity of muscarinic receptors in various brain regions were determined using radioligand binding techniques. Acute DFP treatment resulted in a significant reduction in receptor number only in the brain stem, while chronic treatment caused receptor down-regulation in the brain stem, cerebral cortex, and striatum. There was no change in ligand affinity in any of the brain regions. In sharp contrast, muscarinic receptor function was fully preserved, in terms of coupling of the receptors to increased phosphoinositide hydrolysis in the cerebral cortex, hippocampus, and striatum, or inhibition of cyclic AMP formation in the cerebral cortex or striatum. Therefore, there is a marked lack or correlation between DFP-induced muscarinic receptor down-regulation and receptor desensitization.